Prismatic secondary battery

ABSTRACT

A prismatic secondary battery includes a battery case in a prismatic shape and a battery cover which seals up an opening part of the battery case. The battery cover has a convex part which projects toward the inside of the battery case, faces an inner surface of a side wall part of the battery case, and extends continuously along the entire periphery of the side wall part. Cover thickness of a contact part of the battery cover which is in contact with the upper end of the side wall part of the battery case at a position outside the convex part is greater than ½ of cover thickness of a blockage part blocking up an opening part at a position inside the convex part and is less than the cover thickness of the blockage part.

TECHNICAL FIELD

The present invention relates to a prismatic secondary battery used forthe purpose of vehicle installation, for example.

BACKGROUND ART

Development of lithium-ion secondary batteries with high energy densityserving as power sources of battery electric vehicles and other types ofvehicles has been promoted energetically in recent years. In secondarybatteries for vehicle installation, higher electric current flowsthrough the battery in comparison with secondary batteries for cellularphones or other devices. Therefore, prevention of the mixing of waterinto the battery and the leakage of the electrolyte is highly essentialand the sealability of the battery is a critical issue. Patent Document1, for example, discloses a prismatic secondary battery in which awinding electrode is stored in a battery case, the electrolyte isinjected into the battery case, and thereafter the battery housing ishermetically sealed up with a cover welded to the battery case. That inPatent Document 2 has a structure in which a convex part is formed onthe back side of the cover.

PRIOR ART LITERATURE Patent Documents

-   Patent Document 1: JP-2010-97770-A-   Patent Document 2: JP-2004-31027-A

SUMMARY OF THE INVENTION Problem to be Solved by the Invention

In Patent Document 1, the battery case and the battery cover are joinedtogether by means of welding in order to hermetically seal up thebattery housing. The joining by means of welding increases thereliability of the hermetic sealing. However, a spatter caused in thewelding can mix into the inside of the battery as a metallic foreignmatter and contribute to a minute short circuit.

It is therefore an object of the present invention is to prevent themixing of metallic foreign matters into the battery due to the spatterin the welding of the battery cover to the metallic battery case andthereby provide a prismatic secondary battery with high reliability.

Means for Solving the Problem

A prismatic secondary battery according to the present inventionachieving the above object comprises: a battery case in a prismaticshape which includes a bottom wall part in a rectangular shape, a sidewall part in a prismatic tubular shape extending up from the bottom wallpart, and an opening part being open upward at an upper end of the sidewall part; and a battery cover which is welded to the upper end of theside wall part of the battery case and seals up the opening part. Thebattery cover has a convex part which projects toward an inside of thebattery case, faces an inner surface of the side wall part of thebattery case, and extends continuously along an entire periphery of theside wall part. Cover thickness at a contact part which is in contactwith the upper end of the side wall part of the battery case at aposition outside the convex part is greater than ½ of cover thickness ata blockage part blocking up the opening part at a position inside theconvex part and is less than the cover thickness at the blockage part.

Effect of the Invention

According to the present invention, the mixing of metallic foreignmatters into the battery due to the spatter can be prevented at the timeof the welding of the battery cover to the battery case and a prismaticsecondary battery with high reliability can be provided. Other objects,configurations and advantages will be clarified in the followingdescription of embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an external perspective view of a prismatic secondary batteryaccording to a first embodiment of the present invention.

FIG. 2 is an exploded perspective view of the prismatic secondarybattery according to the first embodiment.

FIG. 3 is an exploded perspective view showing a power generationelement of which a part is opened and extended.

FIG. 4 is a perspective view showing a cover according to the firstembodiment viewed from a lower surface's side.

FIG. 5 is a plan view showing the lower surface of the cover accordingto the first embodiment.

FIG. 6 is a cross-sectional view showing a joint part where a batterycase and the cover are joined together.

FIG. 7 is a cross-sectional view showing a state in which the batterycase and the cover in FIG. 6 are separated from each other.

FIG. 8 is a cross-sectional view showing a joint part where a batterycase and a cover of a prismatic secondary battery in accordance with asecond embodiment of the present invention are joined together.

FIG. 9 is a cross-sectional view showing a state in which the batterycase and the cover in FIG. 8 are separated from each other.

FIG. 10 is a cross-sectional view for explaining a conventional example.

FIG. 11 is a cross-sectional view for explaining another conventionalexample.

MODE FOR CARRYING OUT THE INVENTION

With reference to the drawings, a description will be given in detail ofpreferred embodiments of the present invention.

A prismatic secondary battery according to an embodiment of the presentinvention comprises: a battery case in a prismatic shape which includesa bottom wall part in a rectangular shape, a side wall part in aprismatic tubular shape extending up from the bottom wall part, and anopening part being open upward at an upper end of the side wall part;and a battery cover which is welded to the upper end of the side wallpart of the battery case and seals up the opening part. The batterycover has a convex part which projects toward the inside of the batterycase, faces an inner surface of the side wall part of the battery case,and extends continuously along the entire periphery of the side wallpart. Cover thickness at a contact part which is in contact with theupper end of the side wall part of the battery case at a positionoutside the convex part is greater than ½ of cover thickness at ablockage part blocking up the opening part at a position inside theconvex part and is less than the cover thickness at the blockage part.

First Embodiment

FIG. 1 is an external perspective view of a prismatic secondary batteryaccording to a first embodiment of the present invention.

The prismatic secondary battery C1 comprises a battery case 1 and acover (battery cover) 6. A power generation element 3 (see FIG. 2) isstored in the battery case 1 and an opening part 1 a of the battery case1 is sealed up with the cover 6. The cover 6 is joined to the batterycase 1 by laser welding. A hermetically sealed battery container isformed by the battery case 1 and the cover 6. The cover 6 is equippedwith a positive external terminal 8A and a negative external terminal8B. Via the positive external terminal 8A and the negative externalterminal 8B, the power generation element 3 (see FIG. 2) is electricallycharged or supplies electric power to an external load. The cover 6 isintegrally provided with a gas release vent 10. When the pressure in thebattery container rises, the gas release vent 10 opens, releases gasfrom inside, and reduces the pressure in the battery container, by whichthe safety of the prismatic secondary battery C1 is secured.

Next, the configuration inside the battery case 1 of the prismaticsecondary battery C1 will be described below with reference to FIG. 2.

FIG. 2 is an exploded perspective view of the prismatic secondarybattery according to the present embodiment.

The battery case 1 of the prismatic secondary battery C1 is formed in aso-called prismatic shape. The battery case 1 includes a bottom wallpart 22 in a rectangular shape, a side wall part 21 in a prismatictubular shape extending up from the bottom wall part 22, and an openingpart 1 a being open upward at the upper end of the side wall part 21.The battery case 1 stores the power generation element 3 via aninsulating sheet 2. The power generation element 3 is an electrodeassembly that is formed by a positive electrode body and a negativeelectrode body being flatly wound while a separator is placed betweenthe positive and negative electrode bodies. At both edges of the powergeneration element 3 in the direction of the winding axis, electrodefoil exposed parts 31 c and 32 c not coated with either a positiveelectrode active material mix or a negative electrode active materialmix are formed.

Since the power generation element 3 is flatly wound, the powergeneration element 3 includes a pair of curved parts having semicircularcross-sectional shapes and facing each other and a flat partcontinuously formed between the pair of curved parts. The powergeneration element 3 is inserted into the battery case 1 from one of thecurved parts so that the winding axis direction of the power generationelement 3 coincides with the width direction of the battery case 1. Inthis state, the other curved part of the power generation element 3 issituated at the upper opening of the battery case 1.

At least part of a positive electrode connection part 31 d, serving asthe aforementioned flat part and electrode foil exposed part of thepower generation element 3, is bundled and formed into a shape like aflat plate, overlaid on an end of a positive electrode current collectorplate (current collector terminal) 4A, and connected to the end of thepositive electrode current collector plate 4A. Similarly, at least partof a negative electrode connection part 32 d, serving as theaforementioned flat part and electrode foil exposed part of the powergeneration element 3, is bundled and formed into a shape like a flatplate, overlaid on an end of a negative electrode current collectorplate (current collector terminal) 4B, and connected to the end of thenegative electrode current collector plate 4B.

The other ends of the positive electrode current collector plate 4A andthe negative electrode current collector plate 4B are connected to thepositive external terminal 8A and the negative external terminal 8B,respectively. The positive electrode current collector plate 4A isequipped with current interruption means (fuse) 44 for interrupting theelectric current when excessive current flows. For example, the currentinterruption means 44 is formed by narrowing a part of the positiveelectrode current collector plate 4A so that the narrowed part is blownout (melted and disconnected) by the excessive current to separate thepositive electrode current collector plate 4A into two parts: the powergeneration element 3's side and the positive external terminal 8A'sside. It should be noted while the current interruption means 44 isarranged in the positive electrode current collector plate 4A in thepresent embodiment, the current interruption means 44 may also bearranged in the negative electrode current collector plate 4B or in boththe positive electrode current collector plate 4A and the negativeelectrode current collector plate 4B. The configuration of the currentinterruption means 44 is not limited to the above example as long as theelectric current can be interrupted in case of an abnormality.

For the purpose of the electrical insulation of the positive electrodecurrent collector plate 4A, the negative electrode current collectorplate 4B, the positive external terminal 8A, and the positive externalterminal 8B from the cover 6, the cover 6 is provided with gaskets 5 andinsulating plates 7. An electrolyte is filled into the battery case 1through an injection vent 9. Thereafter, a vent plug 11 is welded to thecover 6 by laser welding to seal up the injection vent 9, by which theprismatic secondary battery C1 is sealed hermetically.

Aluminum or aluminum alloy serving as metallic material is used for thematerial of the battery case 1 and the cover 6. Aluminum or aluminumalloy is used also as the material of the positive electrode currentcollector plate 4A and the positive external terminal 8A. Copper orcopper alloy is used as the material of the negative electrode currentcollector plate 4B and the negative external terminal 8B.

Each of the positive external terminal 8A and the negative externalterminal 8B has a welding joint part to be joined to a bus bar (notshown) or the like by means of welding. The welding joint part is in arectangular prism shape protruding upward from the cover 6. The lowersurface of the welding joint part is opposed to the surface of the cover6. The upper surface of the welding joint part extends in parallel withthe cover 6 at a certain height position.

The lower surface of the welding joint part of the positive externalterminal 8A is integrally provided with a positive electrode connectionpart 12A for connecting the positive external terminal 8A to thepositive electrode current collector plate 4A. The lower surface of thewelding joint part of the negative external terminal 8B is integrallyprovided with a negative electrode connection part 12B for connectingthe negative external terminal 8B to the negative electrode currentcollector plate 4B.

The positive electrode connection part 12A is formed in a cylindricalshape protruding from the lower surface of the positive externalterminal 8A so that its tip end can be inserted into a through hole 6Aof the cover 6. The positive electrode connection part 12A protrudesthrough the cover 6 to reach the inside of the battery case 1 from abasal part 41A of the positive electrode current collector plate 4A. Thetip end of the positive electrode connection part 12A is crimped, bywhich the positive external terminal 8A and the positive electrodecurrent collector plate 4A are integrally fixed on the cover 6. Thegasket 5 is arranged between the cover 6 and the positive externalterminal 8A while the insulating plate 7 is disposed between the cover 6and the positive electrode current collector plate 4A. Similarly, thenegative electrode connection part 12B is formed in a cylindrical shapeprotruding from the lower surface of the negative external terminal 8Bso that its tip end can be inserted into a through hole 6B of the cover6. The negative electrode connection part 12B protrudes through thecover 6 to reach the inside of the battery case 1 from a basal part 41Bof the negative electrode current collector plate 4B. The tip end of thenegative electrode connection part 12B is crimped, by which the negativeexternal terminal 8B and the negative electrode current collector plate4B are integrally fixed on the cover 6. The gasket 5 is arranged betweenthe cover 6 and the negative external terminal 8B while the insulatingplate 7 is disposed between the cover 6 and the negative electrodecurrent collector plate 4B.

The positive electrode current collector plate 4A has the basal part 41Ain a rectangular plate-like shape which is arranged to face the lowersurface of the cover 6 and a connection end part 42A which is bent at alateral edge of the basal part 41A, extended toward the bottom of thebattery case 1 along a wide surface of the battery case 1, overlaid onthe positive electrode connection part 31 d of the power generationelement 3 to face the positive electrode connection part 31 d, andconnected to the positive electrode connection part 31 d. The basal part41A is formed to have an opening 43A into which the positive electrodeconnection part 12A is inserted. Similarly, the negative electrodecurrent collector plate 4B has the basal part 41B in a rectangularplate-like shape which is arranged to face the lower surface of thecover 6 and a connection end part 42B which is bent at a lateral edge ofthe basal part 41B, extended toward the bottom of the battery case 1along the wide surface of the battery case 1, overlaid on the negativeelectrode connection part 32 d of the power generation element 3 to facethe negative electrode connection part 32 d, and connected to thenegative electrode connection part 32 d. The basal part 41B is formed tohave an opening 43B into which the negative electrode connection part12B is inserted.

FIG. 3 is an exploded perspective view showing the power generationelement while opening and extending a part of the power generationelement.

The power generation element 3 is an electrode assembly that is formedby a positive electrode body 31 and a negative electrode body 32 beingflatly wound while a separator 33 is placed between the positive andnegative electrode bodies 31 and 32. The positive electrode body 31 isformed by coating both sides of positive electrode foil 31 a with apositive electrode compound 31 b. The positive electrode body 31 has apositive electrode foil exposed part 31 c (non-coated part) at one edgeof the positive electrode foil 31 a in regard to the width direction.

The negative electrode body 32 is formed by coating both sides ofnegative electrode foil 32 a with a negative electrode compound 32 b.The negative electrode body 32 has a negative electrode foil exposedpart 32 c (non-coated part) at one edge of the negative electrode foil32 a (opposite to the aforementioned edge of the positive electrode foil31 a) in regard to the width direction. The positive electrode body 31and the negative electrode body 32 are wound together in a way that thepositive electrode foil exposed part 31 c and the negative electrodefoil exposed part 32 c are situated on opposite sides in the windingaxis direction.

FIG. 4 is a perspective view showing the cover viewed from the lowersurface's side (i.e., viewed from the inside of the secondary battery).FIG. 5 is a plan view showing the lower surface of the cover facing theinside of the secondary battery.

The cover 6 is in a shape like a flat plate in a size big enough toblock the opening part 1 a of the battery case 1. The cover 6 isprovided with the through holes 6A and 6B, the injection vent 9 and thegas release vent 10. The cover 6 has a blockage part 54 and a contactpart 52. The blockage part 54 extends at a substantially constant coverthickness to block the opening part 1 a. The contact part 52, formedoutside the blockage part 54 at a smaller cover thickness than theblockage part 54, extends along the entire outer peripheral edge of thecover 6 so as to contact the edge part (upper end) of the side wall part21 of the battery case 1.

Inside the contact part 52, a convex part 51 is formed to project towardthe inside of the battery case 1, face the inner surface of the sidewall part 21 of the battery case 1, and extend continuously along theentire periphery of the side wall part 21. Further, a groove 53 isformed inside the convex part 51. The groove 53 is concavely formed inthe blockage part 54.

FIG. 6 is a cross-sectional view showing a joint part where the batterycase and the cover are joined together. FIG. 7 is a cross-sectional viewshowing a state in which the battery case and the cover in FIG. 6 areseparated from each other.

The contact part 52 of the cover 6, while being placed in contact withthe edge part of the side wall part 21 of the battery case 1, is subjectto laser welding from the outside of the battery case 1, that is, fromthe side surface (left side in FIG. 6). A weld part 61 is then formedbetween the contact part 52 of the cover 6 and the edge part of the sidewall part 21 of the battery case 1, by which the cover 6 and the batterycase 1 are joined together. The weld part 61 is formed continuouslyalong the entire outer peripheral edge of the cover 6 to seal up theopening part of the battery case 1.

The convex part 51 faces the inner surface of the side wall part 21 ofthe battery case 1. In this state, a gap can occur between the convexpart 51 and the side wall part 21 of the battery case 1 since thedimension of the convex part 51, in consideration of the dimensionaltolerance, has been set to be smaller than the internal dimension of theside wall part 21 of the battery case 1 so that the convex part 51 canbe fit in the side wall part 21 without much difficulty.

The contact part 52, the convex part 51 and the groove 53 along theentire periphery of the cover 6 can be formed with ease by means ofpress work. The convex part 51 can be formed by use of excess volumecaused in the formation of the contact part 52 and the groove 53 bothhaving smaller cover thicknesses than the blockage part 54. The convexpart 51 is formed so that its projection height from the contact part 52toward the inside of the battery case 1 equals a prescribed height L.With this configuration, the length or distance for which the cover 6and the edge part of the side wall part 21 of the battery case 1 faceeach other can be increased by the height L.

FIG. 10 is a cross-sectional view corresponding to FIG. 6, showing acomparative example for explaining the operational advantages of thepresent embodiment.

In the prismatic secondary battery shown in FIG. 10 as a comparativeexample, a cover 106 is formed in a shape like a flat plate having aconstant thickness Tc. A contact part 152 of the cover 106 is set on anedge part of a side wall part 121 of a battery case 101 before laserwelding is performed between the side wall part 121 and the contact part152 from the side. In this case, the spatter S caused by the laserwelding can pass through a gap between the edge part of the side wallpart 121 and the contact part 152 of the cover 106 and then drop to theinside of the battery case 101.

In particular, in a case where the end depth of a weld part 161 isincreased in order to securely seal up the secondary battery, the lengthH of the gap between the edge part of the side wall part 121 and thecontact part 152 of the cover 106 would decrease along with the increasein the end depth of the weld part 161. The spatter S would easily enterthe battery case 101 as a result.

In contrast, in the present embodiment (see FIG. 6), the cover 6 isprovided with the convex part 51. Consequently, the length of the gapformed between the cover 6 and the edge part of the side wall part 21 ofthe battery case 1 is secured by the length of the convex part 51.Therefore, if the edge part of the side wall part 21 and the contactpart 52 of the cover 6 are joined together by laser welding from theoutside of the battery case 1, it will be possible to have the spatteractively adhere to an inner wall surface 21 a of the side wall part 21or an opposing surface 51 a of the convex part 51 and remain in the gapbetween the side wall part 21 and the convex part 51. As a result, thespatter can be effectively prevented from passing through the gapbetween the edge part of the side wall part 21 and the contact part 52of the cover 6 and dropping to the inside of the battery case 1.

In the case of laser welding, increasing the end depth of the weld part61 would lead to a corresponding rise in the welding width at theproximal end. Thus, in order to carry out the welding deeper and seal upthe secondary battery more securely, the contact part 52 is required tohave a certain cover thickness. In the present embodiment, the coverthickness Tu of the contact part 52 is set greater than ½ of the coverthickness Tt of the blockage part 54 and is less than the coverthickness Tt of the blockage part 54 (Tt/2<Tu<Tt), allowing it to securethe welding area of the weld part 61 as wide as possible and to increasethe depth of the weld part 61.

Increasing the depth of the weld part 61 adversely would lead to adecrease in the length H of the gap between the edge part of the sidewall part 21 and the contact part 52 of the cover 6. In the presentembodiment, however, the cover 6 is provided with the convex part 51.The length of the gap formed between the cover 6 and the edge part ofthe side wall part 21 of the battery case 1 is secured by the height Lof the convex part 51. Therefore, the spatter caused by the laserwelding can be effectively prevented from passing through the gapbetween the edge part of the side wall part 21 and the contact part 52of the cover 6 and dropping to the inside of the battery case 1. Asdescribed above, the mixing of metallic foreign matters into the batterycase 1 due to the spatter can be prevented at the time of the laserwelding of the cover 6 to the battery case 1 performed from the outsideof the battery case 1. Accordingly, a prismatic secondary battery C1with high reliability can be provided.

It should be noted that while an example in which the groove 53 isformed inside the convex part 51 has been described in the aboveembodiment, the configuration of the cover 6 is not limited to thisexample as long as the convex part 51 can be formed to have a prescribedheight. That is, the groove 53 is not a requisite.

Second Embodiment

Next, a second embodiment will be described below with reference toFIGS. 8, 9 and 11.

FIG. 8 is a cross-sectional view showing a joint part where a batterycase and a cover of a prismatic secondary battery according to a secondembodiment of the present invention are joined together. FIG. 9 is across-sectional view showing a state in which the battery case and thecover in FIG. 8 are separated from each other. Elements in FIGS. 8 and 9equivalent to those in the first embodiment are assigned the samereference characters as in the first embodiment and detailed explanationthereof is omitted for brevity.

Characteristic features of the present embodiment are as follows: A step23 is formed in the edge part of the side wall part 21 of the batterycase 1. The battery case 1 is sealed up by fitting the battery cover 6in the side wall part 21 of the battery case 1 and performing laserwelding between the battery cover 6 and the side wall part 21 from abovethe battery case 1.

The edge part of the side wall part 21 of the battery case 1 is formedto have the step 23. The step 23 is continuously formed peripherally onthe inner side of the edge part of the side wall part 21. The contactpart 52 of the cover 6 is placed in contact with the step 23. The laserwelding is performed between the edge part of the side wall part 21 andthe contact part 52 of the cover 6 from above (from the outside of thebattery case 1). By the laser welding, a weld part 62 is formed betweenthe contact part 52 of the cover 6 and the edge part of the side wallpart 21 of the battery case 1. The weld part 62 is formed continuouslyalong the entire outer periphery of the cover 6 to seal up the openingpart of the battery case 1.

The convex part 51 faces the inner side of the side wall part 21 of thebattery case 1 along the entire periphery. In this state, a gap canoccur between the convex part 51 and the side wall part 21 of thebattery case 1 since the dimension of the convex part 51, inconsideration of the dimensional tolerance, has been set to be smallerthan the internal dimension of the side wall part 21 of the battery case1 so that the convex part 51 can be fit in the side wall part 21 withoutmuch difficulty.

FIG. 11 is a cross-sectional view corresponding to FIG. 8, showing acomparative example for explaining the advantages of the presentembodiment.

In the prismatic secondary battery shown in FIG. 11 as a comparativeexample, a cover 106 is formed in a shape like a flat plate having aconstant thickness Tc. A contact part 152 of the cover 106 is set on astep 123 in an edge part of a side wall part 121 and laser welding isperformed between the side wall part 121 and the contact part 152 fromabove the cover 106. As a result, the length for which the side wallpart 121 and the contact part 152 face each other may not be longenough. And hence, the spatter S caused by the laser welding can passthrough a gap between the step 123 of the side wall part 121 and thecontact part 152 of the cover 106 and then drop to the inside of thebattery case 101.

In the laser welding, increasing the end depth of the weld part 162leads to a corresponding rise in the welding width at the proximal end.Thus, the weld part 162 should be preferably situated inward of thebattery case 1 (right side in FIG. 11) in an allowable range. Thisrequires it to reduce the indent Ts of the step 123 from the innersurface of the side wall part 121. Consequently, the length of the gapbetween the edge part of the side wall part 121 and the contact part 152of the cover 6 decreases and the spatter S tends to enter the batterycase 1.

In contrast, in the present embodiment, the cover 6 is provided with theconvex part 51 and because of it, the length of the gap formed betweenthe cover 6 and the edge part of the side wall part 21 of the batterycase 1 is ensured to be at least as great as the length of the convexpart 51 as shown in FIG. 8. Therefore, when laser welding is performedbetween the edge part of the side wall part 21 and the contact part 52of the cover 6 from the outside of the battery case 1, it will bepossible to have the spatter actively adhere to the side wall part 21 orthe convex part 51 and remain in the gap between the side wall part 21and the convex part 51. Accordingly, the spatter caused by the laserwelding can be effectively prevented from passing through the gapbetween the edge part of the side wall part 21 and the contact part 52of the cover 6 and dropping to the inside of the battery case 1.

As described above, the mixing of metallic foreign matters into thebattery due to the spatter can be prevented at the time of the laserwelding of the cover 6 to the battery case 1 performed from the outsideof the battery case 1 and a prismatic secondary battery C1 with highreliability can be provided.

The present invention is not limited to the above embodiments and mayembrace varieties of modifications without departing from the spirit ofthe invention. The embodiments, for example, have only been described indetail for a better understanding of the invention and are therefore notnecessarily limited to the configurations containing all describedconstituent elements. In addition, part of the configuration of acertain embodiment may be replaced by the configuration of anotherembodiment and the configuration of a certain embodiment may be added tothe configuration of another embodiment. Furthermore, part of theconfiguration of one of the embodiments may be added to, deleted from,and/or replaced by the other embodiments.

REFERENCE NUMERALS

-   1 battery case-   1 a opening part-   3 power generation element (electrode assembly)-   4A positive electrode current collector plate (current collector    terminal)-   4B negative electrode current collector plate-   6 cover (battery cover)-   8A positive external terminal (external terminal)-   8B negative external terminal-   12A positive electrode connection part-   12B negative electrode connection part-   21 side wall part-   22 bottom wall part-   51 convex part-   52 contact part-   53 groove-   54 blockage part-   61, 62 weld part-   C1 prismatic secondary battery

1. A prismatic secondary battery comprising: a battery case in aprismatic shape which includes a bottom wall part in a rectangular shapeforming a bottom, a side wall part in a prismatic tubular shape forminga side wall, and an opening part being open upward at an upper end ofthe side wall part; and a battery cover which is welded to the upper endof the side wall part of the battery case and seals the opening part,wherein: the battery cover includes a blockage part which blocks theopening part, a convex part which is positioned outside the blockagepart, and a contact part which is positioned outside the convex part;the side wall part includes a step part on an upper end of the sidewall; the step part contact with the contact part; the convex part isarranged adjacent to the step portion.
 2. The prismatic secondarybattery according claim 1, wherein the convex part is arranged adjacentto a welding part.